DE102014117809A1 - Method and system for online water scrubbing of a compressor with a corrosion protection solution - Google Patents

Abstract

Method (400) and systems (130) can distribute gas turbine corrosion protection. In one embodiment, a method (400) may include determining a state of a gas turbine (11) while the gas turbine (11) is operating, the state including the power output level of the gas turbine (11), and applying a corrosion inhibiting fluid (302) to the gas turbine Gas turbine (11) based on the state while the gas turbine (11) is in operation included.

Description

BACKGROUND TO THE INVENTION

A compressor of a gas turbine may be subject to dust picking and the ingress of occasionally detached foreign matter that bypasses the inlet and results in differential severe impact damage (e.g., corrosion, tip erosion / rubbing, trailing edge thinning, and stator blade erosion). A gas turbine also includes blades and other structures of a turbine, which over time are subject to the deposition of deposits of different residues that are byproducts of the combustion process. Impact damage and deposits of deposits result in a loss of turbine efficiency and potential wear of gas turbine components.

BRIEF SUMMARY OF THE INVENTION

There are disclosed herein methods and systems that impart turbine corrosion protection. In one embodiment, a method may include determining a condition of a gas turbine while the gas turbine is operating, the condition including the power output level of the gas turbine, and applying a corrosion inhibiting fluid to the gas turbine, depending on the condition while the gas turbine is operating ,

In the aforementioned method, the anticorrosion fluid may be applied via a funnel-shaped injection inlet nozzle in the vicinity of a compressor of the gas turbine.

The anticorrosive fluid may include a polyamine-based fluid.

In the method of any of the above-mentioned types, the state of the gas turbine may be based on at least one of: an elapsed time between washes, an elapsed time between applications of anticorrosive fluid, an elapsed service life of the gas turbine, a temperature of the gas turbine, and / or atmospheric conditions near the gas turbine during operation.

Alternatively or additionally, the state of the gas turbine may be based on data from a sensor, wherein the sensor comprises at least one of a pollution sensor, a fluid level sensor, a pressure sensor, a temperature sensor and / or a flow sensor.

In the process of any of the above mentioned types, the anticorrosive fluid may be produced by combining at least two of the following: cyclohexylamine, morpholine, monoethanolamine, N-9-octadecenyl-1,3-propanediamine, 9-octadecene-1-amine, (Z ) -1-5, dimethylaminopropylamine (DMPA), diethylaminoethanol (DEAE) or polyamine.

The method of any type mentioned above may further include maintaining a fuel / compressor exhaust pressure ratio of the gas turbine such that a combustor condition does not lag changes in the airflow while the anticorrosive fluid is applied to the gas turbine.

In the process of the latter type, the corrosion protection fluid may be in the form of a gas.

In one embodiment, a system may include a processor configured to execute computer-readable instructions and a memory communicatively coupled to the processor. Computer-readable instructions may be stored in the memory that, when executed by the processor, cause the processor to perform operations that include determining a condition of a gas turbine while the gas turbine is operating, the condition including a power output level of the gas turbine, and providing instructions to apply a corrosion inhibiting fluid to the gas turbine based on the condition while the gas turbine is operating.

In the aforementioned system, the anticorrosion fluid may be applied via a funnel-shaped injection inlet nozzle in the vicinity of a compressor of the gas turbine.

The anticorrosive fluid may include a polyamine-based fluid.

The condition of the gas turbine may be based on at least one of an elapsed time between washes, an elapsed time between applications of anticorrosive fluid, an elapsed service life of the gas turbine, a temperature of the gas turbine, and / or atmospheric conditions in the vicinity of the gas turbine during operation.

In the system of any of the above-mentioned types, the computer-readable instructions executed by the processor may cause the processor to perform operations further including providing instructions to apply anticorrosive fluid based on the condition of the gas turbine in a predetermined ratio with water to mix.

Additionally or alternatively, the computer readable instructions executed by the processor may cause the processor to perform operations further including providing instructions to maintain a gas turbine fuel / compressor discharge pressure ratio such that a combustor condition does not lag changes in the airflow while the corrosion protection fluid is applied to the gas turbine.

In the system of the latter type, maintaining the fuel / compressor exhaust pressure ratio of the gas turbine may include providing a substantially constant air flow from a compressor of the gas turbine.

In one embodiment, a system may include a turbine engine, a pipe in fluid communication with the turbine engine, a valve connected to the pipe, a source of anticorrosive fluid in fluid communication with the pipe Control system included, which is communicatively connected to the turbine engine.

In the system of the aforementioned further embodiment, the anticorrosive fluid may contain a polyamine-based fluid.

Further, the tube may be in fluid communication with a funnel-shaped injection inlet nozzle proximate a compressor of the turbine engine.

Still further, the system of the further embodiment of any type mentioned above may further comprise a mixing chamber in fluid communication with the corrosion control fluid source and a water source fluidly connected to the mixing chamber, the mixing chamber being based on a mixing chamber Condition of the turbine engine a corrosion inhibitor mixed with the water.

In the system of the last-mentioned type, the anticorrosion agent may contain at least one of cyclohexylamine, morpholine, monoethanolamine, N-9-octadecenyl-1,3-propanediamine, 9-octadecene-1-amine, (Z) -1-5, dimethylaminepropylamine (DMPA ), Diethylaminoethanol (DEAE) and / or polyamine.

This summary of the invention is intended to introduce a selection of concepts in a simplified form, which are described in more detail below in the detailed description. This summary of the invention is not intended to identify basic features or essential features of the claimed subject matter, nor is it intended to limit the scope of the claimed subject matter. Furthermore, the claimed subject matter is not limited to features that eliminate any or all of the disadvantages mentioned in any portion of this disclosure.

BRIEF DESCRIPTION OF THE DRAWINGS

A deeper understanding can be obtained from the following description, given by way of example in connection with the accompanying drawings:

1 shows an exemplary representation of a power plant system;

2 shows a sectional view of a gas turbine having turbine and compressor pipes;

3 shows a schematic representation of an exemplary system for washing or otherwise treating a gas turbine;

4 illustrates a non-limiting example method for applying gas turbine corrosion protection treatment;

5 illustrates, by way of example block diagram, a general purpose computer system in which aspects of the methods and systems or portions thereof described herein, or portions thereof, may be embodied.

DETAILED DESCRIPTION OF THE INVENTION

Compressors of gas turbines operating in harsh environments may experience debris, corrosion, tip erosion / edging, trailing edge thinning, and stator foot erosion. During downtime, blending, polishing, and grinding can be used to reduce the rate of corrosion and further propagation of other damage. Blending has applicability and limitations in that it can not be used to mitigate or eliminate scores and craters that, if left untreated, can most often result in crack propagation and accelerated corrosion.

Disclosed herein are methods and systems for the application of a gas turbine corrosion inhibiting fluid, such as a polyamine-based fluid. As used herein, the term "polyamine" means an organic compound having two or more primary amino groups -NH ₂ . In one embodiment, a corrosion inhibitor may include a volatile neutralizing amine that neutralizes acidic contaminants and raises the pH to an alkaline range and is particularly resistant and adhesive to the metal oxide protective coatings. Non-limiting examples of the corrosion inhibitor include cyclohexylamine, morpholine, monoethanolamine, N-9-octadecenyl-1,3-propanediamine, 9-octadecene-1-amine, (Z) -1-5, dimethylaminopropylamine (DMPA), diethylaminoethanol (DEAE) and the like and / or a combination comprising at least one of the above-mentioned substances. For example, the anticorrosive fluid may contain a combination of a polyamine (a multifunctional organic amine corrosion inhibitor) and neutralizing amines (volatile organic amines).

In one embodiment, existing funnel-shaped injection openings of compressors may be used as a means for distributing a corrosion protection fluid. A corrosion inhibiting fluid may be generated in the compressor section from a mixture of a corrosion inhibitor with water. By varying the valve position, mixtures having different levels of anti-corrosion fluid can be introduced into the compressor.

During operation, this system may have the effect of increasing the "mass flow rate" through the turbine, thereby enabling an increase in the power fed into the grid. Among other things, the corrosion protection fluid can be "misused" or used to increase performance, NO _x reduction or network frequency support and the like. In one embodiment, appropriate logic may be activated to ensure that the anticorrosive fluid is not overused. The application of the anticorrosive fluid may be based on a size of the gas turbine, the duration of a wash in combination with the drain and the flow requirement.

1 shows an exemplary representation of a power plant system 105 , In normal operation, intake air flows over the intake hoods 114 into the inlet filter housing 110 and by several filter elements. The filtered intake air flows through a channel 112 to a gas turbine 116 , The gas turbine 116 has a compressor section 117 , a combustion section 118 and a turbine section 119 on. High pressure air from the compressor section 117 enters the combustion section 118 the gas turbine 116 where the air can be mixed with fuel and burned.

2 shows an exemplary illustration of a gas turbine 11 , which has air valve and pipe components for cooling and sealing of. A compressor 15 can contain a number of levels. As in 2 shown, can be an A-level 54 , a B-stage 55 or a C-stage 56 be present of the compressor. The terms "A-stage", "X-stage" and the like are used herein as opposed to "first stage", "second stage" and the like, to avoid inferring that the systems and methods described herein are in any way unique the use is limited in the context of the actual first stage or the second stage of the compressor or the turbine. Any number of steps can be used. Each stage contains several circumferentially arranged rotating blades, eg blades 59 , Blade 60 and blade 61 , Any number of blades can be used. The blades can be attached to an impeller 65 to be appropriate. The impeller 65 may be rotatably attached to the power output drive shaft. Each stage may also include a plurality of circumferentially spaced stationary vanes 67 contain. Any number of vanes 67 can be used. The vanes 67 can in an outer casing 70 to be appropriate. The housing 70 can be different from a funnel-shaped inlet nozzle 75 in the direction of the turbine 17 extend. The airflow 22 enters the compressor 15 at the funnel-shaped inlet nozzle 75 and is through the blades (including, for example, the blade 59 . 60 and 61 ) and through the vanes 67 the stages compressed before it flows to the combustion chamber.

The gas turbine 11 can also use an air extraction system 80 contain. The air extraction system 80 can be part of the airflow 22 in the compressor 15 tap to use it for cooling the turbine and for other purposes. The air extraction system 80 can have a number of air extraction tubes 85 contain. The air extraction tubes 85 can come from a withdrawal port 90 at one of the compressor stages in the direction of one of the stages of the turbine 17 extend. 2 shows an X-stage sampling tube 92 and a Y-stage extraction tube 94 , The X-stage extraction tube 92 can be at a ninth stage of the compressor 15 be arranged, and the Y-stage extraction tube 94 can be at the thirteenth stage of the compressor 15 be arranged. It can also take samples from other stages of the compressor 15 be used. The X-stage extraction tube 92 Can with an X-stage tube 96 the turbine be fluidly connected while the Y-stage extraction pipe 94 with a Y-stage tube 98 the turbine 17 can be fluidly connected. For example, the X-stage tube 96 a third stage 17 match, and the Y-stage tube 98 can be a second stage of the turbine 17 correspond.

3 illustrates a schematic representation of an exemplary system 130 for washing or otherwise treating a gas turbine, such as the gas turbine 11 , In an exemplary embodiment, the system is 130 adapted to perform on a gas turbine, a laundry, a distribution of a corrosion protection fluid or otherwise treatment in the ongoing operation of the gas turbine. Whether the gas turbine is on the fly can be determined based on a power output level, but usually implies that the gas turbine is operating at higher temperatures (eg, when the turbine is operating at a temperature greater than 145 ° F). A gas turbine may be considered out of service when the engine is operating well below the normal generated output power level.

To feed pipelines 150 includes a water supply pipe 142 in connection with a source 144 of water (eg deionized water) as well as a feed pipeline 146 for cleaning agent (ie a cleaning agent), which is provided with a cleaning agent source 148 connected is. A valve device (not shown) connected to the supply pipes 150 may allow a choice between different sources of fluids.

The system 130 can be a magnesium sulfate pipeline 151 included with a feed 152 a magnesium sulfate aqueous solution is connected. Magnesium sulfate helps prevent the formation of vanadium-based slag, which is favored by the use of heavy crude fuel oils. Each of the water supply piping 142 , the detergent pipeline 146 and the magnesium sulfate feed pipeline 151 may have a pump. Each pump can be a motor (eg motor 322 , Engine 324 and engine 326 ) as well as valves (eg valve 330 . 331 . 332 . 333 . 334 . 335 ) and return circuits (eg flow circuit 340 , Flow circuit 342 and flow circuit 344 ) exhibit.

The water supply pipe 142 , the detergent pipe 146 , the pipeline 306 and the magnesium sulfate feed pipeline 151 are with the mixing chamber 162 fluidly connected. From the mixing chamber 162 may be the combined mixture to the mixture supply manifold 164 be directed. A control system 190 may determine the ratios of fluids (eg, between water and corrosion inhibitors) contained therein (or not included). The output flow from the mixing chamber 162 can be regulated / controlled. The distributor 164 contains a valve 166 and a valve 168 which are coupled and which, in one embodiment, are controlled such that at any one time only either the valve 166 or the valve 168 can be open (but both valves can be closed at the same time). In a modified embodiment, the valve 166 and the valve 168 be separated and independently controllable. There may be multiple mixing chambers connected to multiple fluid sources. For example, there may be a mixing chamber suitable for a source of anticorrosion fluid (eg, an anticorrosive agent feed) 302 ) and for a water source (eg for the water source 142 ) is determined.

The system 130 can a pipeline 306 included with a feed 302 a corrosion inhibitor is connected. A connection 304 (ie a quick coupler) for an external supply (eg by a truck with a corrosion inhibitor) is connected to the pipeline 306 connected. The Pipe arrangements in the exemplary system 130 can via a feed branch 170 be fluidly connected with funnel-shaped nozzles. The piping arrangements in the exemplary system 130 can via a feed branch 172 be fluidly connected to other distribution systems (eg inlet tap heat, mist generator or evaporative cooler).

In one embodiment, only water and one or more corrosion inhibitors may be mixed in a predetermined ratio. In one embodiment, corrosion inhibitors and other fluids may pass through the mixing chamber 162 mixed and over the fluidly connected pipe 306 in the chamber 302 be introduced (there may be several storage or supply units, with the mixing chamber 162 are connected). Then that can be in the supply 302 existing anti-corrosive fluid through the fluidly connected pipe 306 over the feeder branch 170 be pumped to the fluidly connected funnel-shaped nozzles. The mixing does not necessarily have to be in the mixing chamber as disclosed herein 162 take place, and it may, for example, a water / corrosion inhibitor mixture be kept in a separate storage tank (eg, in 302 a premixed anticorrosive fluid is filled).

The mixture for the anticorrosive fluid may be based on the size of the gas turbine, duration of a wash in combination with the drain or flow requirement. The ratio can also be adjusted based on the type of amine.

4 illustrates a non-limiting example method 400 for applying a gas turbine corrosion protection treatment. In one embodiment, in step 405 the state of the gas turbine (eg the compressor) can be determined. The condition may be determined based on sensors or the like. The condition may include readiness for anti-corrosive use, eg, whether the compressor is clean (eg, free of particulate matter or dust), whether a gas turbine is in service (eg, out of service or in service), how long the gas turbine has been operating , or the temperature of a compressor and the same. The state of cleanliness of the gas turbine may be determined by data from fouling sensors, by the elapsed time between cleanings, or by sensors detecting atmospheric conditions during operation of the gas turbine, and the like.

In step 410 For example, the type of anticorrosion fluid to be applied to the gas turbine can be determined based on the condition of the gas turbine. The state of the gas turbine may include the output power level of the gas turbine or the like. In one embodiment, the type of anticorrosive fluid to be applied to the gas turbine may be determined based on a distribution point to the gas turbine. For example, the type of anticorrosive fluid may be selected based on whether the distribution is via funnel-shaped nozzles near the funnel-shaped inlet or via the extraction ports (or other ports) near later stages.

In step 415 For example, a corrosion inhibiting fluid may be applied to the gas turbine based on the condition of the gas turbine. If a compressor is contaminated in the application of anticorrosive fluid, the anticorrosive fluid may not adhere properly to the compressor components, which in turn may reduce the effectiveness of the anticorrosive fluid employed. In one embodiment, the anti-corrosive fluid may be applied after cleaning a gas turbine.

Although the anticorrosive fluid may be substantially heat resistant, a corrosion inhibiting fluid may become ineffective at certain temperatures. Therefore, it may be desirable to apply or not apply the anticorrosive fluid as a function of temperature at a particular stage of the gas turbine component at the particular stage of the gas turbine component (eg, the compressor or turbine). The point of application of the anticorrosive fluid may be through valves (eg three-way valve 174 and three-way valve 184 ) controlled by a control system (eg, the control system) 190 ), as described herein, are fluidly connected. The valves may be automatically or manually controlled based on a threshold condition (eg, above or below a certain temperature).

In an exemplary embodiment, the control system communicates 190 wirelessly or hard-wired with the sensors described herein, and additionally communicates with actuators (not shown) provided to start, stop, or control the speed of motors. The control system can open, close or control the position of valves used to control the operations of the system 130 to accomplish, as described here.

The control system 190 may be a computer system communicatively connected to a control panel / display. The control system 190 can run programs to the operation of the system 130 to control by means of sensor inputs and commands from operators. In addition, the control system 190 in one embodiment, to alter (or restrict) the ratio of water to polyamine or other anticorrosion agent, to alter (or limit) wash cycle cycle times, or to alter the order of steps in wash or rinse cycles (or limit). Such aspects of the treatment process may be selected by a turbine manufacturer to suit the specifications and design of the turbine to be treated.

The control system 190 is how in 3 shown communicatively connected to systems and devices of the power plant. If all of the given logic allowing for the application of the anticorrosive fluid is met, the on-line fluid treatment may be activated by the anticorrosive fluid and the anticorrosive fluid may be used appropriately. The control system 190 For example, the gas turbine may automatically operate based on a predetermined / pre-designed sequence specifically designed for a corrosion protection fluid operating mode. The method of activating and operating the fluid handling system while in operation includes determining that the power output and other turbine control parameters are met for on-the-fly fluid handling. The control system 190 may attempt to maintain a substantially constant airflow from the compressor to assist in controlling a fuel / compressor discharge pressure ratio such that a combustor condition does not lag changes in the airflow during the fluid treatment sequence. During operation, this system will have the effect of increasing the "mass flow rate" through the turbine, thereby allowing an increase in the power supplied to the grid. Taking into account the aforementioned, the control system 190 be set up with the appropriate controls and restrictions to ensure that it is not used with a view to an increase in output, NO _x reduction or mains frequency support excessively (eg waste) can be.

During application of the anticorrosion fluid (eg, via funnel-shaped nozzles, via an inlet bleed heat system, an evaporative cooling system, and the like), the control system may 190 in one embodiment, configured to issue commands to a gas turbine to maintain an adequate power output level. An appropriate level of performance may be manually adjusted, determined by analysis of the current or similar gas turbines, or the like. In one embodiment, overuse may be minimized by restricting access to a change in control logic for on-the-fly use (eg, anti-corrosive fluid). For example, minimal access to a change in the ratio of anticorrosion agent to water for on-the-fly application of anticorrosive fluid, minimal access to cycle time change for antisurge fluid sequences during operation (eg, between fluid applications), minimal access to cycle time change for one Application during operation (eg during a fluid application) or the like. Excessive use of fluids during operation or other use of the anticorrosive fluid may be indicated by patterns in frequency and other data as suggested herein with respect to the application of the anticorrosion fluid.

Without intending to limit the scope, interpretation, or application of the claims appearing herein in any way, a technical effect described herein relies on the use of a combination of chemicals (ie, corrosion inhibitors) in a ratio of acidic and alkaline chemicals to temperature-conducive Environmental conditions to assist in the formation of a passivation layer on the surface of compressor blades and stator vanes of gas turbines. The ratio can be predetermined. Reducing corrosion can help maintain a restored performance for a longer duration. The use of the corrosion inhibitor can reduce the tendency of compressor blades to erode due to numerous water scrubbing operations. The incorporation of the corrosion protection distribution system into existing systems as described herein may minimize the need for new extensive piping or housing penetration installations.

5 and the following discussion is intended to provide a brief general description of a suitable computing environment in which the methods and systems and / or portions thereof described herein may be practiced. Although not required, portions of the methods and systems disclosed herein are described in the general context of computer-executable instructions. eg as program modules that are executed by a computer, for example by a client workstation, a server, personal computer or a mobile computing device, eg a smartphone. Program modules generally include program routines, programs, objects, components, data structures, and the like that perform specific tasks or set up specific abstract data types. Moreover, it should be understood that the methods and systems and / or portions thereof described herein may be used in practice in conjunction with other computer system arrangements, such as hand-held devices, multiprocessor systems, microprocessor-based or programmable consumer electronics, network PCs, minicomputers, mainframe computers, and the like like. A processor may be performed on a single chip, multiple chips, or multiple electronic devices having different architectures. The methods and systems disclosed herein may also be used in distributed computing environments where tasks are performed by remotely located processing units linked by a communications network. In a distributed computing environment, program modules may be located in both local and remote memory storage devices.

5 illustrates a block diagram of a general purpose computer system in which aspects of the methods and systems described herein and / or portions thereof may be integrated. As shown, the exemplary general purpose computer system includes a computer 520 or the like, with a processor unit 521 , a system memory 522 and a system bus 523 , the different system components, including the system memory, with the processor unit 521 combines. The system bus 523 may include any type of bus architecture, such as a memory bus or memory controller, a peripheral bus, and a local bus using any bus architecture. The system memory contains a read-only memory (ROM) 524 and random access memory (RAM) 525 , A basic input / output system 526 (BIOS), which contains the basic program routines that allow the transfer of information between items in the computer 520 , eg during startup, is in the ROM 524 saved.

The computer 520 may also have a hard disk drive 527 for reading from or writing to a hard disk (not shown), a magnetic disk drive 528 for reading from or writing to a removable magnetic disk 529 , and an optical disk drive 530 for reading from or writing to a removable optical storage disc 531 For example, a CD-ROM or other optical media included. The hard disk drive 527 , the magnetic disk drive 528 and the optical disk drive 530 are with the system bus 523 through a hard drive interface 532 , a magnetic disk drive interface 533 or an optical drive interface 534 connected. The drives and their associated computer-readable media enable non-volatile storage of computer-readable instructions, data structures, program modules, and other data for the computer 520 , As described herein, a computer-readable medium is a tangible, physical, and concrete article of manufacture, and thus not a signal as such.

Although the example environment described here is a hard disk, a removable magnetic disk 529 and a removable optical storage disc 531 It is understood that other types of computer-readable media that can store data that a computer can access may also be used in the example operating environment. Such other types of media include, but are not limited to, a magnetic cartridge, a flash memory card, a digital video or versatile disk (DVD), a Bernoulli box, Random Access Memory (RAM), an optional Read-only memory (ROM) and the like.

Several program modules can be on the hard disk, the magnetic disk 529 , the optical storage disc 531 , the ROM 524 or the RAM 525 stored, for example, an operating system 535 , one or more application programs 536 , other program modules 537 and program data 538 , A user can use input devices, such as a keyboard 540 and a pointing device 542 , Control commands and data in the computer 520 enter. Other input devices (not shown) may include a microphone, a joystick, a gamepad, a satellite dish, a scanner, or the like. These and other input devices are often replaced by a serial interface 546 which is connected to the system bus, with the processor unit 521 however, may also be connected by other interfaces, such as a parallel port, game port channel, or universal serial bus (USB). A monitor 547 or another type of display device is also via an interface, such as a video adapter 548 , with the system bus 523 connected. In addition to the monitor 547 For example, a computer may include other peripheral output devices (not shown), such as speakers and printers. The exemplary system of 5 also includes a host adapter 555 , a small one Computer system interface (SCSI) bus 556 and an external storage device 562 that with the SCSI bus 556 connected is.

The computer 520 can work in a networked environment that makes logical connections to one or more remote computers, such as a remote computer 549 , used. The remote computer 549 may be a personal computer, server, router, network PC, peer device, or other common network node and may do many or all of the above related to the computer 520 contain described elements, although in 5 only a memory device 550 is illustrated. In the 5 illustrated logical connections include a local area network (LAN) 551 and a wide area network (WAN) 552 , Such network operating environments are standard in offices, corporate computer networks, intranets, and the Internet.

If the computer 520 in a LAN network operating environment, it is through a network interface or adapter 553 with the LAN 551 connected. If the computer 520 in a WAN network operating environment, it can use a modem 554 or other means for data communications over the wide area network 552 eg the internet. The modem 554 , which can be internal or external, is via the serial port 546 with the system bus 523 connected. In a networked environment can with respect to the computer 520 displayed program modules or parts thereof may be stored in the remote memory device. It will be understood that the network connections shown are exemplary and that other means of establishing a communication link between the computer may be used.

The computer 520 can contain a variety of computer-readable storage media. Computer-readable storage media may be any available media to which the computer 520 include both volatile and non-volatile media, removable and non-removable media. For example, and not by way of limitation, computer-readable media may include computer storage media and communication media. Computer storage media includes both volatile and nonvolatile, removable and non-removable media used in any methods or technologies for storing data such as computer-readable instructions, data structures, program modules or other data. Computer storage media include, but are not limited to, RAM, ROM, EEPROM, flash memory or other storage technology, CD-ROM, digital versatile disks (DVDs) or other optical disk storage, magnetic cassettes, magnetic tape, magnetic disk storage or other magnetic storage devices or any other media that can be used to store the information you want and the computer you want 520 can be accessed. Additionally, combinations of any of the above-mentioned elements should fall within the scope of computer-readable media that may be used to store source code for implementing the methods and systems described herein. Any combination of the features or elements described herein may be used in one or more embodiments.

In describing embodiments of the subject matter of the disclosure as illustrated in the figures, specific terminology is used for the sake of clarity. However, the claimed subject matter should not be limited to the specific terminology so selected, and it is understood that each particular element includes all technical equivalents that operate similarly to achieve a similar purpose. By means of the systems described herein, an atomized anticorrosion fluid, a vaporous anticorrosive fluid, or a non-atomized liquid anticorrosive fluid may be used. As used herein, a fluid is a substance that does not have a solid shape and yields to an external pressure, such as a gas, a liquid, an aerosol, or the like. Although a gas turbine has been discussed for a power plant system, other similar turbine designs are contemplated. The anticorrosive fluid discussed herein may be applied simultaneously or separately via different systems, e.g. via an inlet bleed heat system, an evaporative cooling system, a funnel-shaped nozzle, via bleed pipes, or through other piping or devices. Any combination of the features or elements described herein with respect to a corrosion protection fluid may be used in one or more embodiments.

This written description uses examples to describe the invention, including the best mode, and also to enable any person skilled in the art to practice the invention, for example, make and use any devices and systems, and any to carry out the procedures. The patentable scope of the invention is defined by the claims, and may include other examples of skill in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims.

method 400 and systems 130 Gas turbines can distribute a corrosion protection. In one embodiment, a method 400 determining a state of a gas turbine 11 while the gas turbine 11 is in operation, the state of the power output level of the gas turbine 11 includes, and applying a corrosion protection fluid 302 on the gas turbine 11 based on the condition while the gas turbine 11 in operation is included. PARTS LIST Ident component figure 105 Power system 1 114 inlet hoods 1 110 filter housing 1 112 channel 1 117 compressor 1 118 combustion section 1 116 gas turbine 1 119 turbine 1 11 gas turbine 2 15 compressor 2 17 turbine 2 22 airflow 2 54 A stage 2 55 B-stage 2 56 C-stage 2 59 blade 2 60 blade 2 61 blade 2 65 Wheel 2 67 vanes 2 75 Funnel-shaped inlet nozzle 2 80 Air extraction system 2 85 Air discharge pipes 2 90 extraction port 2 92 X-stage extraction tube 2 94 Y-stage extraction tube 2 96 X-stage pipe 2 98 Y stage tube 2 130 system 3 170 delivery branch 3 172 delivery branch 3 166 Valve 3 168 Valve 3 164 supply manifold 3 302 Corrosion inhibitors supply 3 306 piping 3 304 quick coupling 3 162 piping 3 330 Valve 3 332 Valve 3 334 Valve 3 322 engine 3 324 engine 3 326 engine 3 344 Flow circuit 3 342 Flow circuit 3 340 Flow circuit 3 331 Valve 3 333 Valve 3 335 Valve 3 151 Supply pipelines 3 142 Water supply pipe line 3 146 Cleaner pipe 3 148 Cleaner source 3 144 water source 3 152 Supply of water-based magnesium sulfate solution 3 190 Regulatory / control system 3 405 Block of the procedure 400 4 410 Block of the procedure 400 4 415 Block of the procedure 400 4 420 Block of the procedure 400 4 425 Block of the procedure 400 4 520 computer 5 521 processor unit 5 522 System memory 5 523 system 5 524 ROME 5 525 R.A.M. 5 526 BIOS 5 528 Floppy Drive 5 529 Storage 5 530 optical drive 5 531 Storage 5 532 Hard disk drive interface 5 533 Magnetic disk drive interface 5 534 Optical drive interface 5 535 operating system 5 536 application programs 5 537 Other programs 5 538 program data 5 540 keyboard 5 542 mouse 5 546 Serial interface 5 547 monitor 5 548 video adapter 5 549 Remote computers 5 550 Storage 5 551 Local network 5 552 Wide area network 5 553 Network Interface 5 554 modem 5 555 Host Adapter 5 556 SCSI BUS 5 562 storage device 5

Claims (10)

A method comprising: Determining a state of a gas turbine while the gas turbine is operating, the state including a power output level of the gas turbine; and Applying a corrosion inhibiting fluid to the gas turbine based on the condition while the gas turbine is in operation. The method of claim 1, wherein the anticorrosive fluid is applied via a funnel-shaped injection inlet nozzle in the vicinity of a compressor of the gas turbine. The method of claim 1 or 2, wherein the condition of the gas turbine is at least one of an elapsed time between laundry operations, an elapsed time between applications of the anticorrosive fluid, an elapsed service life of the gas turbine, a temperature of the gas turbine, and / or atmospheric conditions in the vicinity of the gas turbine based on the operation; and / or wherein the state of the gas turbine is based on data from a sensor, wherein the sensor includes at least one of a fouling sensor, a fluid level sensor, a pressure sensor, a temperature sensor and / or a flow sensor. A method according to any one of the preceding claims, wherein the anticorrosion fluid is produced by combining at least two of the following: cyclohexylamine, morpholine, monoethanolamine, N-9-octadecenyl-1,3-propanediamine, 9-octadecene-1-amine, (Z) -1-5, dimethylaminopropylamine (DMPA), diethylaminoethanol (DEAE) or polyamine; and / or wherein the anticorrosive fluid contains a polyamine-based fluid. The method of claim 1, further comprising: maintaining a fuel / compressor exhaust pressure ratio of the gas turbine such that a combustor state does not lag changes in the airflow while the anticorrosive fluid is applied to the gas turbine; wherein the corrosion protection fluid is preferably in the form of a gas. System that includes: a processor configured to execute computer-readable instructions; and a memory communicatively coupled to the processor, the memory storing the computer readable instructions that, when executed by the processor, cause the processor to perform operations comprising: Determining a state of a gas turbine while the gas turbine is operating, the state including a power output level of the gas turbine; and Providing instructions to apply a corrosion inhibiting fluid to the gas turbine based on the condition while the gas turbine is operating. The system of claim 6, wherein the computer-readable instructions executed by the processor cause the processor to perform operations further comprising: Providing instructions to mix the anticorrosion fluid with water in a predetermined ratio based on the state of the gas turbine. The system of claim 6 or 7, wherein the computer readable instructions executed by the processor cause the processor to perform operations further comprising: Providing instructions to maintain a fuel / compressor exhaust pressure ratio of the gas turbine such that a combustor condition does not lag changes in the airflow while the anticorrosive fluid is applied to the gas turbine; wherein maintaining the fuel / compressor discharge pressure ratio of the gas turbine preferably includes supplying a substantially constant air flow from a compressor of the gas turbine. System that includes: a turbine engine; a pipe in fluid communication with the turbine engine; a valve connected to the pipe; a source of anticorrosive fluid containing a corrosion control fluid, the source in fluid communication with the tube; and a control system communicatively connected to the turbine engine. The system of claim 9, further comprising: a mixing chamber in fluid communication with the source of anticorrosive fluid; and a water source in fluid communication with the mixing chamber, the mixing chamber mixing a corrosion inhibitor based on a state of the gas turbine with the water.

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